use super::internal::*;
use super::*;

/// This trait abstracts the different ways we can "unzip" one parallel
/// iterator into two distinct consumers, which we can handle almost
/// identically apart from how to process the individual items.
trait UnzipOp<T>: Sync + Send {
    /// The type of item expected by the left consumer.
    type Left: Send;

    /// The type of item expected by the right consumer.
    type Right: Send;

    /// Consume one item and feed it to one or both of the underlying folders.
    fn consume<FA, FB>(&self, item: T, left: FA, right: FB) -> (FA, FB)
        where FA: Folder<Self::Left>,
              FB: Folder<Self::Right>;

    /// Reports whether this op may support indexed consumers.
    /// - e.g. true for `unzip` where the item count passed through directly.
    /// - e.g. false for `partition` where the sorting is not yet known.
    fn indexable() -> bool {
        false
    }
}

/// Run an unzip-like operation into `ParallelExtend` collections.
fn execute<I, OP, FromA, FromB>(pi: I, op: OP) -> (FromA, FromB)
    where I: ParallelIterator,
          OP: UnzipOp<I::Item>,
          FromA: Default + Send + ParallelExtend<OP::Left>,
          FromB: Default + Send + ParallelExtend<OP::Right>
{
    let mut a = FromA::default();
    let mut b = FromB::default();
    {
        // We have no idea what the consumers will look like for these
        // collections' `par_extend`, but we can intercept them in our own
        // `drive_unindexed`.  Start with the left side, type `A`:
        let iter = UnzipA {
            base: pi,
            op: op,
            b: &mut b,
        };
        a.par_extend(iter);
    }
    (a, b)
}


/// Unzips the items of a parallel iterator into a pair of arbitrary
/// `ParallelExtend` containers.
///
/// This is not directly public, but called by `ParallelIterator::unzip`.
pub fn unzip<I, A, B, FromA, FromB>(pi: I) -> (FromA, FromB)
    where I: ParallelIterator<Item = (A, B)>,
          FromA: Default + Send + ParallelExtend<A>,
          FromB: Default + Send + ParallelExtend<B>,
          A: Send,
          B: Send
{
    execute(pi, Unzip)
}

/// Unzip an `IndexedParallelIterator` into two arbitrary `Consumer`s.
///
/// This is not directly public, but called by `super::collect::unzip_into`.
pub fn unzip_indexed<I, A, B, CA, CB>(pi: I, left: CA, right: CB) -> (CA::Result, CB::Result)
    where I: IndexedParallelIterator<Item = (A, B)>,
          CA: Consumer<A>,
          CB: Consumer<B>,
          A: Send,
          B: Send
{
    let consumer = UnzipConsumer {
        op: &Unzip,
        left: left,
        right: right,
    };
    pi.drive(consumer)
}

/// An `UnzipOp` that splits a tuple directly into the two consumers.
struct Unzip;

impl<A: Send, B: Send> UnzipOp<(A, B)> for Unzip {
    type Left = A;
    type Right = B;

    fn consume<FA, FB>(&self, item: (A, B), left: FA, right: FB) -> (FA, FB)
        where FA: Folder<A>,
              FB: Folder<B>
    {
        (left.consume(item.0), right.consume(item.1))
    }

    fn indexable() -> bool {
        true
    }
}


/// Partitions the items of a parallel iterator into a pair of arbitrary
/// `ParallelExtend` containers.
///
/// This is not directly public, but called by `ParallelIterator::partition`.
pub fn partition<I, A, B, P>(pi: I, predicate: P) -> (A, B)
    where I: ParallelIterator,
          A: Default + Send + ParallelExtend<I::Item>,
          B: Default + Send + ParallelExtend<I::Item>,
          P: Fn(&I::Item) -> bool + Sync + Send
{
    execute(pi, Partition { predicate: predicate })
}

/// An `UnzipOp` that routes items depending on a predicate function.
struct Partition<P> {
    predicate: P,
}

impl<P, T> UnzipOp<T> for Partition<P>
    where P: Fn(&T) -> bool + Sync + Send,
          T: Send
{
    type Left = T;
    type Right = T;

    fn consume<FA, FB>(&self, item: T, left: FA, right: FB) -> (FA, FB)
        where FA: Folder<T>,
              FB: Folder<T>
    {
        if (self.predicate)(&item) {
            (left.consume(item), right)
        } else {
            (left, right.consume(item))
        }
    }
}


/// Partitions and maps the items of a parallel iterator into a pair of
/// arbitrary `ParallelExtend` containers.
///
/// This is not directly public, but called by `ParallelIterator::partition_map`.
pub fn partition_map<I, A, B, P, L, R>(pi: I, predicate: P) -> (A, B)
    where I: ParallelIterator,
          A: Default + Send + ParallelExtend<L>,
          B: Default + Send + ParallelExtend<R>,
          P: Fn(I::Item) -> Either<L, R> + Sync + Send,
          L: Send,
          R: Send
{
    execute(pi, PartitionMap { predicate: predicate })
}

/// An `UnzipOp` that routes items depending on how they are mapped `Either`.
struct PartitionMap<P> {
    predicate: P,
}

impl<P, L, R, T> UnzipOp<T> for PartitionMap<P>
    where P: Fn(T) -> Either<L, R> + Sync + Send,
          L: Send,
          R: Send
{
    type Left = L;
    type Right = R;

    fn consume<FA, FB>(&self, item: T, left: FA, right: FB) -> (FA, FB)
        where FA: Folder<L>,
              FB: Folder<R>
    {
        match (self.predicate)(item) {
            Either::Left(item) => (left.consume(item), right),
            Either::Right(item) => (left, right.consume(item)),
        }
    }
}


/// A fake iterator to intercept the `Consumer` for type `A`.
struct UnzipA<'b, I, OP, FromB: 'b> {
    base: I,
    op: OP,
    b: &'b mut FromB,
}

impl<'b, I, OP, FromB> ParallelIterator for UnzipA<'b, I, OP, FromB>
    where I: ParallelIterator,
          OP: UnzipOp<I::Item>,
          FromB: Default + Send + ParallelExtend<OP::Right>
{
    type Item = OP::Left;

    fn drive_unindexed<C>(self, consumer: C) -> C::Result
        where C: UnindexedConsumer<Self::Item>
    {
        let mut result = None;
        {
            // Now it's time to find the consumer for type `B`
            let iter = UnzipB {
                base: self.base,
                op: self.op,
                left_consumer: consumer,
                left_result: &mut result,
            };
            self.b.par_extend(iter);
        }
        // NB: If for some reason `b.par_extend` doesn't actually drive the
        // iterator, then we won't have a result for the left side to return
        // at all.  We can't fake an arbitrary consumer's result, so panic.
        result.expect("unzip consumers didn't execute!")
    }

    fn opt_len(&mut self) -> Option<usize> {
        if OP::indexable() {
            self.base.opt_len()
        } else {
            None
        }
    }
}

/// A fake iterator to intercept the `Consumer` for type `B`.
struct UnzipB<'r, I, OP, CA>
    where I: ParallelIterator,
          OP: UnzipOp<I::Item>,
          CA: UnindexedConsumer<OP::Left>,
          CA::Result: 'r
{
    base: I,
    op: OP,
    left_consumer: CA,
    left_result: &'r mut Option<CA::Result>,
}

impl<'r, I, OP, CA> ParallelIterator for UnzipB<'r, I, OP, CA>
    where I: ParallelIterator,
          OP: UnzipOp<I::Item>,
          CA: UnindexedConsumer<OP::Left>
{
    type Item = OP::Right;

    fn drive_unindexed<C>(self, consumer: C) -> C::Result
        where C: UnindexedConsumer<Self::Item>
    {
        // Now that we have two consumers, we can unzip the real iterator.
        let consumer = UnzipConsumer {
            op: &self.op,
            left: self.left_consumer,
            right: consumer,
        };

        let result = self.base.drive_unindexed(consumer);
        *self.left_result = Some(result.0);
        result.1
    }

    fn opt_len(&mut self) -> Option<usize> {
        if OP::indexable() {
            self.base.opt_len()
        } else {
            None
        }
    }
}


/// `Consumer` that unzips into two other `Consumer`s
struct UnzipConsumer<'a, OP: 'a, CA, CB> {
    op: &'a OP,
    left: CA,
    right: CB,
}

impl<'a, T, OP, CA, CB> Consumer<T> for UnzipConsumer<'a, OP, CA, CB>
    where OP: UnzipOp<T>,
          CA: Consumer<OP::Left>,
          CB: Consumer<OP::Right>
{
    type Folder = UnzipFolder<'a, OP, CA::Folder, CB::Folder>;
    type Reducer = UnzipReducer<CA::Reducer, CB::Reducer>;
    type Result = (CA::Result, CB::Result);

    fn split_at(self, index: usize) -> (Self, Self, Self::Reducer) {
        let (left1, left2, left_reducer) = self.left.split_at(index);
        let (right1, right2, right_reducer) = self.right.split_at(index);

        (UnzipConsumer {
             op: self.op,
             left: left1,
             right: right1,
         },
         UnzipConsumer {
             op: self.op,
             left: left2,
             right: right2,
         },
         UnzipReducer {
             left: left_reducer,
             right: right_reducer,
         })
    }

    fn into_folder(self) -> Self::Folder {
        UnzipFolder {
            op: self.op,
            left: self.left.into_folder(),
            right: self.right.into_folder(),
        }
    }

    fn full(&self) -> bool {
        // don't stop until everyone is full
        self.left.full() && self.right.full()
    }
}

impl<'a, T, OP, CA, CB> UnindexedConsumer<T> for UnzipConsumer<'a, OP, CA, CB>
    where OP: UnzipOp<T>,
          CA: UnindexedConsumer<OP::Left>,
          CB: UnindexedConsumer<OP::Right>
{
    fn split_off_left(&self) -> Self {
        UnzipConsumer {
            op: self.op,
            left: self.left.split_off_left(),
            right: self.right.split_off_left(),
        }
    }

    fn to_reducer(&self) -> Self::Reducer {
        UnzipReducer {
            left: self.left.to_reducer(),
            right: self.right.to_reducer(),
        }
    }
}


/// `Folder` that unzips into two other `Folder`s
struct UnzipFolder<'a, OP: 'a, FA, FB> {
    op: &'a OP,
    left: FA,
    right: FB,
}

impl<'a, T, OP, FA, FB> Folder<T> for UnzipFolder<'a, OP, FA, FB>
    where OP: UnzipOp<T>,
          FA: Folder<OP::Left>,
          FB: Folder<OP::Right>
{
    type Result = (FA::Result, FB::Result);

    fn consume(self, item: T) -> Self {
        let (left, right) = self.op.consume(item, self.left, self.right);
        UnzipFolder {
            op: self.op,
            left: left,
            right: right,
        }
    }

    fn complete(self) -> Self::Result {
        (self.left.complete(), self.right.complete())
    }

    fn full(&self) -> bool {
        // don't stop until everyone is full
        self.left.full() && self.right.full()
    }
}


/// `Reducer` that unzips into two other `Reducer`s
struct UnzipReducer<RA, RB> {
    left: RA,
    right: RB,
}

impl<A, B, RA, RB> Reducer<(A, B)> for UnzipReducer<RA, RB>
    where RA: Reducer<A>,
          RB: Reducer<B>
{
    fn reduce(self, left: (A, B), right: (A, B)) -> (A, B) {
        (self.left.reduce(left.0, right.0), self.right.reduce(left.1, right.1))
    }
}
